Advances in Carbon Materials for Sodium and Potassium Storage

Liu, Mingquan; Wang, Yahui; Wu, Feng; Bai, Ying; Liu, Ying; Gong, Yuteng; Feng, Xin; Wang, Xinran; Wu, Chuan

doi:10.1002/adfm.202203117

Cited by 63 publications

(49 citation statements)

References 489 publications

(853 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Fewer carriers migrated in the tensile areas, but more carriers migrated in compressed areas through closer interconnection. [32,34,35] 3) Sodium/zinc ions or PEDOT long-chain molecules self-interacted with cellulose/carbon further facilitated [36] electrolytes diffusion and offered a mixed conduction mechanism. [37] Thus, through modulation of the interspacing of nanoflakes, this carbon paper guaranteed the realization of next-generation flexible electronics by ensuring available electrical contact in dynamic conditions, where the electric/electrochemical performance depended on re-stacking morphologies, and material composition.…”

Section: Resultsmentioning

confidence: 99%

Cellulose‐Derived Wearable Carbon Nanoflake Sensors Customized by Semiconductor Laser Photochemistry

Tao

Zhang

et al. 2023

Advanced Sensor Research

View full text Add to dashboard Cite

Multi‐functional wearable electrical materials have been regarded as one of the most pivotal cornerstones for the booming internet of things (IoTs), biomimetic robotics/science, and sensory e‐skins. Nevertheless, customizable, high‐throughput, batch‐fabricated, function‐integrated wearable electronics remain technologically challenging to traditional material engineering. Hereby, a cellulose‐converted active amorphous carbon nanomaterial is developed via a transfer‐free, precursor‐free rapid laser synthesis method incorporating deformation‐tolerant waste papers. The lattice fringe spacing of laser‐synthesized carbon nanoflake is ≈0.305 nm topologically distinct from graphene or carbon dots. The nanostructured three‐dimensional (3D) carbon network exhibits desirable mechanical flexibility, high hygroscopicity/electrical conductivity, large ion storing capacity for Zn2+ or Na+, high sensitivity to pressure, and a natural microwave absorbing ratio (> 37 dB at the terahertz range). Abundant percolation pathways inside cellulose/carbon composite networks offered fast electrolyte diffusion and carrier mobility. A series of low‐cost highly‐deformable interdigitated supercapacitors, tactile sensors, electrical circuits, and functional coatings are experimentally fabricated and identified, enabling waste paper as a function‐magnified meta platform for e‐skins, wearable energy devices, or IoTs interfaces.

show abstract

Section: Resultsmentioning

confidence: 99%

Cellulose‐Derived Wearable Carbon Nanoflake Sensors Customized by Semiconductor Laser Photochemistry

Tao

Zhang

et al. 2023

Advanced Sensor Research

View full text Add to dashboard Cite

show abstract

“…Recently, the as-reported works on the dual-doping of carbonaceous materials involve a N, O dual-doped hard carbon anode ( Adams et al, 2017 ; Gong et al, 2019 ), P, N dual-doped carbon ( Gan et al, 2019 ), P, O dual-doped graphene ( Zhao et al, 2021 ), and so on. The dual-doping strategy has been also used on flexible carbon-based substrates in consideration of its synergistic effect on the electrode surface ( Liu et al, 2022 ). Zeng et al (2020) designed flexible a N, O dual-doped carbon-coated graphene foam film (NOC@GF), where the N, O doped hard carbon layer boosts K + adsorption and the graphene layer shows a low resistance for K + diffusion ( Figure 3A ).…”

Section: Modification Strategies Of Carbon-based Flexible Anodes For ...mentioning

confidence: 99%

Emerging carbon-based flexible anodes for potassium-ion batteries: Progress and opportunities

Yang

Zuo

et al. 2022

Front. Chem.

View full text Add to dashboard Cite

In recent years, carbon-based flexible anodes for potassium-ion batteries are increasingly investigated owing to the low reduction potential and abundant reserve of K and the simple preparation process of flexible electrodes. In this review, three main problems on pristine carbon-based flexible anodes are summarized: excessive volume change, repeated SEI growth, and low affinity with K+, which thus leads to severe capacity fade, sluggish K+ diffusion dynamics, and limited active sites. In this regard, the recent progress on the various modification strategies is introduced in detail, which are categorized as heteroatom-doping, coupling with metal and chalcogenide nanoparticles, and coupling with other carbonaceous materials. It is found that the doping of heteroatoms can bring the five enhancement effects of increasing active sites, improving electrical conductivity, expediting K+ diffusion, strengthening structural stability, and enlarging interlayer spacing. The coupling of metal and chalcogenide nanoparticles can largely offset the weakness of the scarcity of K+ storage sites and the poor wettability of pristine carbon-based flexible electrodes. The alloy nanoparticles consisting of the electrochemically active and inactive metals can concurrently gain a stable structure and high capacity in comparison to mono-metal nanoparticles. The coupling of the carbonaceous materials with different characteristics can coordinate the advantages of the nanostructure from graphite carbon, the defects and vacancies from amorphous carbon, and the independent structure from support carbon. Finally, the emerging challenges and opportunities for the development of carbon-based flexible anodes are presented.

show abstract

“…The development of efficient and safe devices for energy storage and utilization is among the most important fields of research in modern society. To this end, in addition to improving established lithium-ion battery technologies, advanced secondary batteries are being actively developed [1][2][3][4]. In particular, research on sodium (Na)-based batteries has increased rapidly since the early 2010s because the raw materials required are inexpensive, abundant, and less toxic raw materials than those required for other similar batteries [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Improving ionic conductivity of von-Alpen-type NASICON ceramic electrolytes via magnesium doping

Jang¹,

Go²,

Song³

et al. 2023

Journal of Advanced Ceramics

View full text Add to dashboard Cite

NASICON (sodium superionic conductor) compounds have attracted considerable attention as promising solid electrolyte materials for advanced sodium (Na)-based batteries. In this study, we investigated the improvement in ionic conductivities of von-Alpen-type NASICON (vA-NASICON) Journal of Advanced Ceramics https://mc03.manuscriptcentral.com/jacer 2 ceramic electrolyte by introducing magnesium (Mg 2+ ) as a heterogeneous element. The optimal Mgdoped vA-NASICON exhibited a high ionic conductivity of 3.64 × 10 −3 S cm −1 , that was almost 80% higher than that of un-doped vA-NASICON. The changes in the physicochemical properties of vA-NASICONs through Mg introduction were systematically analyzed, and their effects on the ionic conductivities of vA-NASICON were studied in detail. When the optimal ratio of Mg 2+ was used in the synthetic process, the relative density (96.6%) and grain boundary ion conductivity were maximized, which improved the total ionic conductivity of vA-NASICON. However, when Mg 2+ was introduced in excess, the ionic conductivity decreased because of the formation of an undesired NaxMgyPO4 secondary phase. The results of this study are expected to be effectively applied in the development of advanced sodium-based solid electrolytes with high ionic conductivities.

show abstract

Advances in Carbon Materials for Sodium and Potassium Storage

Cited by 63 publications

References 489 publications

Cellulose‐Derived Wearable Carbon Nanoflake Sensors Customized by Semiconductor Laser Photochemistry

Cellulose‐Derived Wearable Carbon Nanoflake Sensors Customized by Semiconductor Laser Photochemistry

Emerging carbon-based flexible anodes for potassium-ion batteries: Progress and opportunities

Improving ionic conductivity of von-Alpen-type NASICON ceramic electrolytes via magnesium doping

Contact Info

Product

Resources

About